Metacognitive Learning Approach for Online Tool Condition Monitoring
Mahardhika Pratama, Eric Dimla, Chow Yin Lai, Edwin Lughofer

TL;DR
This paper introduces a novel metacognitive learning approach for online tool condition monitoring that enhances decision-making by focusing on what to learn and when to learn, improving accuracy and reducing complexity.
Contribution
It proposes a new metacognitive framework based on scaffolding theory integrated with rClass, addressing traditional machine learning limitations in TCM.
Findings
rClass achieved highest accuracy in experiments
rClass maintained lowest complexity among compared methods
The approach effectively predicts tool failures on the fly
Abstract
As manufacturing processes become increasingly automated, so should tool condition monitoring (TCM) as it is impractical to have human workers monitor the state of the tools continuously. Tool condition is crucial to ensure the good quality of products: Worn tools affect not only the surface quality but also the dimensional accuracy, which means higher reject rate of the products. Therefore, there is an urgent need to identify tool failures before it occurs on the fly. While various versions of intelligent tool condition monitoring have been proposed, most of them suffer from a cognitive nature of traditional machine learning algorithms. They focus on the how to learn process without paying attention to other two crucial issues: what to learn, and when to learn. The what to learn and the when to learn provide self regulating mechanisms to select the training samples and to determine…
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